通过底物掺入聚乙二醇来工程细胞运动

R. Sharma, J. Kohn, P. Moghe
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引用次数: 0

摘要

本研究检测了细胞对蛋白质吸附聚乙二醇(PEG)变异体共聚物迁移反应的调节。为此,纤维连接蛋白在基于酪氨酸/PEG衍生聚碳酸酯家族的共聚物上被吸附到等效水平。原子力显微镜(AFM)显示了每个共聚物体系独特的蛋白质分布,这表明尽管存在等量的配体,但底物中PEG的浓度会影响所吸附的配体。因此,蛋白质吸附共聚物上纤维连接蛋白rgd结合位点的定量显示,在中等浓度的PEG下,细胞结合位点最大。我们的迁移研究表明,增加共聚物中的PEG单调增加了细胞速度,直到达到最大速度的中间PEG水平。在配体吸附共聚物上培养细胞后,相对于中等水平的PEG,较高水平的PEG引发了相同数量的细胞结合位点。整合素抑制研究表明,/spl α //sub 5//spl β //sub 1/在调节RGD位点数量中起关键作用。我们的AFM数据表明,静电斥力促进了较高PEG水平的重排,影响了聚合物表面的纤维连接蛋白滑移以及揭示添加RGD结合位点的构象重排。总的来说,我们报告了一项发现,细胞对给定配体浓度的迁移反应可以通过由底物PEG组成的系统配体变化进一步操纵。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Engineering cell motility via substrate incorporation of poly(ethylene glycol)
This study examined the modulation of cell migratory responsiveness to protein-adsorbed poly(ethylene glycol) (PEG) variant copolymers. To this end, fibronectin was adsorbed to equivalent levels on copolymers based on a family of tyrosine/PEG derived polycarbonates. Atomic force microscopy (AFM) revealed unique protein distributions for each copolymer system, indicating that although equal amounts of ligand are presented, the concentration of PEG in the underlying substrate can effect the adsorbed ligand. Consequently, quantitation of fibronectin RGD-binding sites on the protein-adsorbed copolymers revealed that cell-binding sites were maximized at intermediate concentrations of PEG. Our migration studies demonstrated that increasing PEG in the copolymer increased cell speed monotonically up to an intermediate PEG level where a maximum speed was reached. After incubating cells on ligand adsorbed copolymers, higher PEG levels elicited equivalent number of cell-binding sites relative to those on intermediate levels of PEG. Integrin inhibition studies showed that /spl alpha//sub 5//spl beta//sub 1/ was critical in modulating the number of RGD sites. Our AFM data suggests that rearrangement at higher PEG levels was facilitated by electrostatic repulsion, effecting fibronectin slippage at the polymer surface as well as conformational rearrangement revealing addition al RGD binding sites. Overall, we report on the finding that cell migratory responsiveness to a given ligand concentration can be further manipulated via systematic ligand changes due to the substrate PEG composition.
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